Stephan De Wekker; Yubao Liu; Jason C. Knievel; Sandip Pal; George D. Emmitt, 2013. Observations and simulations of the wind structure in the boundary layer around an isolated mountain during the MATERHORN field experiment. A14D-05.
Chow, An immersed boundary method in WRF for complex mountainous terrain.
James D. Doyle; David C. Fritts; Ronald B. Smith; Stephen D. Eckermann; Michael J. Taylor. Exploring Gravity Wave Dynamics and Predictability in DeepWave A13L-01.
H.J.S. Fernando. MATERHORN Program Overview
Joshua Hacker. The Potential Utility of High Resolution Ensemble Sensitivities During Weak Flow in Complex Terrain
Higgins, C.W., S.W. Hoch, and E. Pardyjak, 2013. The Temperature Gradient and Transition Timescales as a Function of Topography in Complex Terrain. A14D-07.
Pal, S., S.F.J. De Wekker, G.D. Emmitt, and MATERHORN Investigators, 2013: Investigation of the spatio-temporal variability of atmospheric boundary layer depths over mountainous terrain observed with a suite of ground-based and airborne instruments during the MATERHORN field experiment.
Pardyjak, E., S.W. Hoch. D.D. Jensen, N.Gunawardena, S. Di Sabatino, C.D. Whiteman, L. Leo, C.M. Hocut, C.W. Higgins, and H.J.S. Fernando, 2013. The effect of shadow fronts on dynamics of the surface layer during evening transitions. A14D-03.
Stefano Serafin, Stephan F.J. de Wekker and Jason C. Knievel, 2013: Boundary-layer phenomena in the vicinity of an isolated mountain: A climatography based on an operational high-resolution forecast system. A13L-04.
Silver, Z. High resolution WRF Modeling
Y. Wang; E. Creegan; M. Felton; G. Huynh; C. Hocut; H. Fernando; S. Hoch; D. Whiteman. Application of Triple Doppler Wind Lidars for the Study of Atmospheric Boundary Layer over a Mountainous Area
